MINT facilities
Being part of a multidisciplinary research center means not needing to have everything yourself! The MINT center is equipped with a full suite of deposition, characterization, and lithogrophy tools, which we make extensive use of. Below, we describe some of our own equipment, which is also shared with other MINT faculty.Facilities in the LeClair lab
Electrical characterization
The most basic characterization on a finished device structure, and arguably the most technologically important, is the measurement of the electrical transport characteristics. We perform a wide variety of electrical transport measurements (current, voltage, and their derivatives) as a funciton of temperature, magnetic field and other variables. Our main system is a Quantum Design Physical Property Measurement System (PPMS). This system allows measurements in a controlled temperature and magnetic field environment, with temperatures ranging from 0.3-400K (with a 3He insert) and magnetic fields from 0-7T. The entire system is computer controlled, allowing programmed temperature, current, or field sweeps during a measurement.
![[photo]](./images/ppms.png)
The PPMS system and external electronics.
![[photo]](./images/electronics.png)
A block diagram of what we usually do.
Inelastic tunneling spectroscopy: (IETS) is a powerful technique utilized to characterize tunneling structures. IETS involves measuring derivatives of the tunneling current-voltage characteristics (dI/dV and d2I/dV2) in order to probe more sensitively the changes in conductance properties when excitations occur as a part of the tunneling process. IETS has been used extensively in the past to probe vibrational modes in tunnel barrier materials (it may be considered complementary to Raman or IR spectroscopy), and more recently, to probe magnetic excitations in MTJs. The unique advantage of IETS is that it provides information only on those processes that influence transport.
For more information: P.K. Hansma, "Tunneling Spectroscopy", Plenum Press, New York (1982); E.L. Wolf , "Principles of Electron Tunneling Spectroscopy", Oxford University Press, London (1985)
Spin-polarized tunneling: one of our main and most powerful tools for assessing prototype structures will be the Meservey-Tedrow spin polarized tunneling (SPT) technique. SPT is a direct and unambiguous manner measure of the spin polarization (P) of tunneling electrons - the only direct method with direct relevance for the TMR effect. It utilizes a superconducting electrode as a spin detector, with the ability to probe within about 1meV of the Fermi energy (i.e., the order of the superconducting energy gap).
In superconductor-insulator-normal metal tunneling, dI/dV(V) is proportional to the BCS density of states.31 The SPT technique achieves spin sensitivity by applying a magnetic field (2-3T) parallel to the film plane. If the superconductor is sufficiently thin (4-5nm), such that the orbital screening currents are negligible, the effects of the electron spin interacting with the magnetic field may be observed. The result is Zeeman splitting of the states in the superconductor, which can be used to probe the spin polariation of tunneling electrons.
The SPT technique has crucial advantages over, e.g., TMR or point contact Andreev reflection. One is the ability to measure the sign (majority or minority) of the spin polarization. From our point of view, another crucial advantage is that a robust, well-tested and microscopic theory of SPT has been developed over the years. This, coupled with the simple, fundamental nature of the experiment makes SPT much more agreeable for detailed comparison with theory. Though restricted to low temperatures and bias voltages, SPT is an ideal technique for our synergistic experimental and theoretical approach to these novel spintronic systems, which require at this stage more fundamental characterization. Complimentary to the SPT experiments, we still utilize the TMR effect to judge the efficiency of spin transport in structures more closely resembling real devices.
For more information: R. Meservey and P.M. Tedrow, "Spin-polarized electron tunneling", Phys. Rep. 238, 173-234(1994); here [pdf], or here [pdf]
Optical characterization
During spring/summer 2007, we started a small effort to investigate optically active spin electronic devices. This started as a summer research project for an undergraduate intern (REU), and the initial successes led to the initiation of a new research focus. Currently, two graduate students are involved at some level in this project.As a requirement for this project, I purchased a simple UV-Visible-Near Infrared spectrophotometer. The system we have (Ocean Optics USB4000 + tungsten-deuterium source) allows one to shine light of a particular wavelength (from 200nm-1000nm) onto a sample and measure the amount of light reflected or transmitted from that sample at any wavelength within the instrument's range. The incident wavelength of light as well as the detected wavelength can be varied over the whole 200-1000nm range, which allows one to measure the wavelength and energy-dependence of light absorption and reflection from a sample. The ability to have different incident and measured wavelengths allows one to measure, e.g., Raman modes or fluorescence behavior.
The system consists of a tungsten-deuterium light source coupled with a wavelength selector (monochromator), which allows one to illuminate a sample with only one wavelength of light, fiber optic cables to guide the light to a desired point, and a spectrometer to measure the absolute light intensity at a particular wavelength. The whole system is controlled through an existing PC using a USB interface. Also included are optical accessories, such as a reference 'leg' fiber (to calibrate the output light intensity), various fiber and spectrometer holders to aid in positioning, control software, and the necessary cabling.
This equipment will allow us to carefully measure the optical properties of materials as a function of light energy, which helps us determine (for example) how efficiently prototype photodetectors and solar cells can convert light energy into electrical energy. The Ocean Optics design we have chosen in particular is perfectly suited to our needs and substantially more inexpensive than competing systems.